Process for producing acicular goethite particles and acicular magnetic iron oxide particles

ABSTRACT

Disclosed herein are a process for producing acicular goethite particles comprising the step off: blowing an oxygen-containing gas into a ferrous salt reaction solution containing colloidal ferrous hydroxide or iron-containing colloidal precipitates which is obtained by reacting an aqueous ferrous salt solution with less than one equivalent of an aqueous alkali hydroxide solution, an aqueous alkali carbonate solution, or an aqueous alkali hydroxide and alkali carbonate solution based on Fe 2+  in said aqueous ferrous salt solution, in the presence of ascorbic acid or a salt thereof so as to oxidize said colloidal ferrous hydroxide or iron-containing colloidal precipitates and to produce acicular goethite particles throught green rust; and a process for producing acicular magnetic iron oxide particles by reducing the acicular goethite particles obtained in the above process to produce acicular magnetite particles, and if necessary, oxidizing the acicular magnetite particles to obtain acicular maghemite particles, and if necessary, modifying the acicular magnetite or maghemite particles with Co or Co and Fe 2+ .

This is a division of application Ser. No. 08/022,847 filed Feb. 25,1993 allowed as U.S. Pat. No. 5,378,380, which is a division of Ser. No.07/733,726, filed Jul. 22, 1991, now abandoned.

BACKGROUND OF THE INVENTION

The present invention relates to a process for producing aciculargoethite particles which are suitable as a starting material formagnetic particles for magnetic recording, and which have a uniformparticle size distribution, are substantially free of dendrites and havea large aspect ratio (major axial diameter/minor axial diameter). Thepresent invention also relates to a process for producing acicularmagnetic iron oxide particles which have a uniform particle sizedistribution, are substantially free of dendrites, and have a largeaspect ratio (major axial diameter/minor axial diameter) and anexcellent coercive force distribution.

With progressing miniatirization and weight-reduction of magneticrecording and reproducing apparatuses in recent years, the necessity fora recording medium having a higher performance such as a magnetic tapeand a magnetic disk has been increasing more and more. In other words, amagnetic recording medium is required to have a higher recordingdensity, higher sensitivity and higher output characteristic. Themagnetic characteristics of magnetic particles which are demanded inorder to satisfy the above-mentioned requirements for the magneticrecording medium, are a high coercive force and an excellentdispersibility.

In order to improve the sensitivity and the output of a magneticrecording medium, the magnetic particles must have as high a coerciveforce as possible. This fact is described in, for example, DEVELOPMENTOF MAGNETIC MATERIALS AND TECHNIQUE OF IMPROVING THE DISPERSION PROPERTYOF MAGNETIC POWDER (1982), published by K. K. Sogo Gijutsu KaihatsuCenter, p.310: "Since the improvement of magnetic tapes has beendirected toward a higher sensitivity and a higher output, it is animportant point to enhance the coercive force of acicular γ-Fe₂ O₃particles, . . ."

In order to improve the recording density of a magnetic recordingmedium, the magnetic recording medium must have a high coercive forceand a large residual magnetization (Br), as described in the saidDEVELOPMENT OF MAGNETIC MATERIALS AND TECHNIQUE OF IMPROVING THEDISPERSION PROPERTY OF MAGNETIC POWDER. p. 312: "The condition forhigh-density recording in a coating-type tape is that it is possible tokeep the high output characteristics with respect to a short-wavelengthsignal at a low noise level. For this purpose, it is necessary that boththe coercive force (Hc) and the residual magnetization (Br) are large,and that the thickness of the coating film is thin". It is thereforenecessary that the magnetic particles have a high coercive force andthey are excellent in dispersibility in the vehicle, and orientationproperty and packing density in the coating film.

In order to enhance the output of a magnetic recording medium, it isrequired to have a small switching field distribution (hereinunderreferred to as "S.F.D.") and hence, the magnetic particles are requiredto have a small width of coercive force distribution. This fact isdescribed in Japanese Patent Application Laid-Open (KOKAI) No. 63-26821(1988): "FIG. 1 is a graph showing the relationship between the S.F.D.of the above-described magnetic disk and the recording and reproducingoutput . . . The relationship between the S.F.D. and the recording andreproducing output is linear, as is clear from FIG. 1. It indicates thatthe recording and reproducing output is enhanced by using ferromagneticpowder having a small S.F.D. That is, in order to obtain a large output,an S.F.D. of not more than 0.6 is necessary.

As well known, the coercive force of magnetic iron oxide particlesdepend upon the configurational anisotropy, crystalline anisotropy,strain anisotropy, exchange anisotropy, or the interaction thereof.

Acicular magnetite particles and acicular maghemite particles which areused as magnetic iron oxide particles at present show a relatively highcoercive force by utilizing the anisotropy derived from their shapes,namely, by increasing the aspect ratio (major axial diameter/minor axialdiameter).

The known acicular magnetic particles are obtained by reducing as astarting material goethite particles or hematite particles obtained byheat-treating the goethite particles, in a reducing gas such as hydrogento form magnetite particles or iron based metal particles or by furtheroxidizing the thus-obtained magnetite particles in air to form maghemiteparticles.

The known acicular magnetic iron oxide particles modified with Co or Coand Fe²⁺ are obtained by dispersing acicular magnetite particles oracicular maghemite particles as the precursor particles in an alkalinesuspension containing cobalt hydroxide or an alkaline suspensioncontaining cobalt hydroxide and ferrous hydroxide so that 0.1 to 21.0atomic % of Co based on Fe of the precursor particles is contained, andheat-treating the resultant dispersion.

The residual magnetization (Br) in a magnetic recording medium dependsupon the dispersibility of the magnetic particles in the vehicle, andthe orientation property and packing density of the magnetic particlesin the coated film, and in order to improve these properties, themagnetic particles to be dispersed in the vehicle are required to haveas large an aspect ratio (major axial diameter/minor axial diameter) aspossible, a uniform particle size distribution and no inclusion ofdendrites.

As described above, magnetic iron oxide particles which have asubstantially uniform particle size distribution, which aresubstantially free of dendtritess and which have a large aspect ratio(major axial diameter/minor axial diameter), are now in the strongestdemand. In order to obtain magnetic iron oxide particles provided withthese properties, it is necessary that as a starting material goethiteparticles have a substantially uniform particle size distribution, aresubstantially free of dendrites and have a large aspect ratio (majoraxial diameter/minor axial diameter).

Various attempts have been made to produce acicular goethite particleswhich have a uniform particle size distribution and are substantiallyfree of dendrites. For example, Japanese Patent Application Laid-Open(KOKAI) No. 2-293330 (1990) discloses a method of producing aciculargoethite particles by adding ascorbic acid or a salt thereof to thesuspension containing ferrous hydroxide which is obtained by reacting anaqueous ferrous salt solution with not less than 1.0 equivalent of anaqueous alkali hydroxide and blowing an oxygen-containing gas into thesuspension.

Magnetic iron oxide particles which have a uniform particle sizedistribution, are substantially free of dendtritess, and have a largeaspect ratio (major axial diameter/minor axial diameter) and anexcellent coercive force distribution are now in the strongest demand.The particles obtained by the method described in Japanese PatentApplication Laid-Open (KOKAI) No.2-293330 (1990) have an aspect ratio(major axial diameter/minor axial diameter) of at the most 10 to 11 andcannot be said to have a large aspect ratio (major axial diameter/minoraxial diameter). The method includes the step of adding an alkalineearth metal in addition to an ascorbic acid or a salt thereof. But inthis case, the aspect ratio (major axial diameter/minor axial diameter)is at the most 15. The acicular magnetic iron oxide particles producedfrom as a starting material these goethite particles have a uniformparticle size distribution and are substantially free of dendrites, butthe aspect ratio (major axial diameter/minor axial diameter) thereof isreduced to 1/2 to 1/3 after they are subjected to heat treatment.

Accordingly, it is an object of the present invention to provideacicular goethite particles which have a uniform particle sizedistribution, are substantilally free of dendrites and have a largeaspect ratio (major axial diameter/minor axial diameter) and acicularmagnetic iron oxide particles further having excellent coercive forcedistribution in addition to the above-described properties.

As a result of studies undertaken by the present inventors, it has beenfound that by blowing an oxygen-containing gas into a ferrous saltreaction solution containing colloidal ferrous hydroxide oriron-containing colloidal precipitates which is obtained by reacting anaqueous ferrous salt solution with less than one equivalent of anaqueous alkali hydroxide solution, an aqueous alkali carbonate solutionor an aqueous alkali hydroxide and alkali carbonate solution based onFe²⁺ in the aqueous ferrous salt solution so as to oxidize the colloidalferrous hydroxide or iron-containing colloidal precipitates and toproduce acicular goethite particles through green rust, ascorbic acid ora salt thereof and, if necessary, a zinc compound being added to any ofthe solutions before the production of the acicular goethite particles,or by blowing an oxygen-containing gas into a ferrous salt reactionsolution containing colloidal ferrous hydroxide or iron-containingcolloidal precipitates which is obtained by reacting an aqueous ferroussalt solution with less than one equivalent of an aqueous alkalihydroxide solution, an aqueous alkali carbonate solution or an aqueousalkali hydroxide and alkali carbonate solution based on Fe²⁺ in theaqueous ferrous salt solution so as to oxidize the colloidal ferroushydroxide or iron-containing colloidal precipitates and to produceacicular goethite nucleus particles through green rust, ascorbic acid ora salt thereof and, if necessary, a zinc compound being added to any ofthe solutions before the production of the acicular goethite nucleusparticles; and growing the acicular goethite nucleus particles so as toproduce acicular goethite particles, the thus-obtained acicular goethiteparticles and acicular magnetic iron oxide particles have a uniformparticle size distribution, are substantially free of dendrites, andhave a large aspect ratio (major axial diameter/minor axial diameter)and excellent coercive force distribution. On the basis of this finding,the present invention has been achieved.

SUMMARY OF THE INVENTION

In a first aspect of the present invention, there is provided a processfor producing acicular goethite particles comprising the step of:blowing an oxygen-containing gas into a ferrous salt reaction solutioncontaining colloidal ferrous hydroxide or iron-containing colloidalprecipitates which is obtained by reacting an aqueous ferrous saltsolution with less than one equivalent of an aqueous alkali hydroxidesolution, an aqueous alkali carbonate solution or an aqueous alkalihydroxide and alkali carbonate solution based on Fe²⁺ in said aqueousferrous salt solution, in the presence of ascorbic acid or a saltthereof and if necessary, a zinc compound so as to oxidize saidcolloidal ferrous hydroxide or iron-containing colloidal precipitatesand to produce acicular goethite particles through green rust.

In a second aspect of the present invention, there is provided a processfor producing acicular goethite particles comprising the steps of:blowing an oxygen-containing gas into a ferrous salt reaction solutioncontaining colloidal ferrous hydroxide or iron-containing colloidalprecipitates which is obtained by reacting an aqueous ferrous saltsolution with less than one equivalent of an aqueous alkali hydroxidesolution, an aqueous alkali carbonate solution or an aqueous alkalihydroxide and alkali carbonate solution based on Fe²⁺ in the aqueousferrous salt solution, in the presence of ascorbic acid or a saltthereof and if necessary, a zinc compound so as to oxidize the colloidalferrous hydroxide or iron-containing colloidal precipitates and toproduce acicular goethite nucleus particles through green rust; andgrowing the acicular goethite nucleus particles so as to produceacicular goethite particles.

In a third aspect of the present invention, there is provided a processfor producing acicular magnetic iron oxide particles comprising thesteps of: blowing an oxygen-containing gas into a ferrous salt reactionsolution containing colloidal ferrous hydroxide or iron-containingcolloidal precipitates which is obtained by reacting an aqueous ferroussalt solution with less than one equivalent of an aqueous alkalihydroxide solution, an aqueous alkali carbonate solution or an aqueousalkali hydroxide and alkali carbonate solution based on Fe²⁺ in theaqueous ferrous salt solution, in the presence of ascorbic acid or asalt thereof and if necessary, a zinc compound so as to oxidize thecolloidal ferrous hydroxide or iron-containing colloidal precipitatesand to produce acicular goethite particles through green rust; or ifnecessary, using the acicular goethite particles produced through greenrust as acicular goethite nucleus particles and growing the producedacicular goethite nucleus particles so as to produce acicular goethiteparticles; heat-treating in a reducing gas the acicular goethiteparticles or acicular hematite particles obtained by heat-treating theacicular goethite particles at 300° to 700° C., thereby obtainingacicular magnetite particles; and if necessary, oxidizing the acicularmagnetite particles, thereby obtaining acicular maghemite particles.

In a fourth aspect of the present invention, there is provided a processfor producing acicular magnetic iron oxide particles comprising thesteps of: blowing an oxygen-containing gas into a ferrous salt reactionsolution containing colloidal ferrous hydroxide or iron-containingcolloidal precipitates which is obtained by reacting an aqueous ferroussalt solution with less than one equivalent of an aqueous alkalihydroxide solution, an aqueous alkali carbonate solution, or an aqueousalkali hydroxide and alkali carbonate solution based on Fe²⁺ in theaqueous ferrous salt solution, in the presence of ascorbic acid or asalt thereof and if necessary, a zinc compound so as to oxidize thecolloidal ferrous hydroxide or iron-containing colloidal precipitatesand to produce acicular goethite particles through green rust; or ifnecessary using the acicular goethite particles produced through greenrust as the acicular goethite nucleus particles and growing the producedacicular goethite nucleus particles so as to produce acicular goethiteparticles; heat-treating in a reducing gas the acicular goethiteparticles or acicular hematite particles obtained by heat-treating theacicular goethite particles at 300° to 700° C., thereby obtainingacicular magnetite particles; oxidizing if necessary, the acicularmagnetite particles, thereby obtaining acicular maghemite particles;dispersing the acicular magnetite particles or the acicular maghemiteparticles as precursor particles in an alkaline suspension containingcobalt hydroxide or cobalt hydroxide and ferrous hydroxide so that theCo content in the suspension is 0.1 to 21.0 atomic % based on Fe of theprecursor particles; and heat-treating the resultant aqueous dispersion,thereby obtaining acicular magnetite particles or acicular maghemiteparticle modified (coated) with Co or Co and Fe²⁺.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an electron micrograph (×30000) of the particle structure ofthe acicular goethite nucleus particles obtained in Example 1;

FIG. 2 is an electron micrograph (×30000) of the particle structure ofthe acicular goethite particles obtained in Example 1;

FIG. 3 is an electron micrograph (×30000) of the particle structure ofthe acicular goethite nucleus particles obtained in Example 3;

FIG. 4 is an electron micrograph (×30000) of the particle structure ofthe acicular goethite particles obtained in Example 3;

FIG. 5 is an electron micrograph (×30000) of the particle structure ofthe acicular goethite nucleus particles obtained in Comparative Example1;

FIG. 6 is an electron micrograph (×30000) of the particle structure ofthe acicular goethite particles obtained in Comparative Example 1;

FIG. 7 is an electron micrograph (×30000) of the particle structure ofthe acicular goethite particles obtained in Comparative Example 2; and

FIG. 8. is an electron micrograph (×30000) of the particle structure ofthe acicular goethite particles obtained in Comparative Example 3.

DETAILED DESCRIPTION OF THE INVENTION

As an aqueous ferrous salt solution used in the present invention, anaqueous ferrous sulfate solution and an aqueous ferrous chloridesolution may be used.

As an aqueous alkali hydroxide solution used for producing aciculargoethite nucleus particles in the present invention, an aqueous sodiumhydroxide solution and an aqueous potassium hydroxide solution areusable. As an aqueous alkali carbonate solution, an aqueous sodiumcarbonate solution, an aqueous potassium carbonate solution and anaqueous ammonium carbonate solution are usable.

The mount of aqueous alkali hydroxide solution or aqueous alkalicarbonate solution used in the present invention is less than oneequivalent based on Fe²⁺ in the aqueous ferrous salt solution. If it isnot less than one equivalent, it is very difficult to obtain goethiteparticles having a large aspect ratio (major axial diameter/minor axialdiameter).

The mount of existent acicular goethite nucleus particles in the presentinvention is not less than 10 mol % based on the total mount of goethiteparticles produced. If it is less than 10 mol %, it is difficult toarise the growing reaction of the acicular goethite nucleus whilemaintaining the form thereof, so that it is very difficult to obtain theobjective acicular geothite particles.

Ascorbic acid or a salt thereof in the present invention influences theform such as the particle size, the presence or absence of dendrites andan aspect ratio (major axial diameter/minor axial diameter) of theacicular goethite particles produced. It is therefore necessary thatascorbic acid or a salt thereof is existent in a solution before theacicular geothite particles are produced. Ascorbic acid or a saltthereof may be added to any of the aqueous ferrous salt solution,aqueous alkali hydroxide solution, aqueous alkali carbonate solution,ferrous salt reaction solution containing colloidal ferrous hydroxide oriron-containing colloidal precipitates, and the reaction solution whichis producing green rust.

As a salt of ascorbic acid, sodium ascorbate, etc. is usable.

The amount of ascorbic acid or a salt thereof added is 0.01 to 5.0 mol %calculated as ascorbic acid based on Fe in the ferrous salt reactionsolution containing colloidal ferrous hydroxide or iron-containingcolloidal precipitates. If it is less than one 0.01 mol %, the objectivegoethite particles which have a uniform particle size distribution, noinclusion of dendrites and a large aspect ratio (major axialdiameter/minor axial diameter), cannot be obtained. If it exceeds 5.0mol %, the major axial diameter of acicular goethite particles producedis small and, hence, the aspect ratio (major axial diameter/minor axialdiameter) is also small, so that it is impossible to obtain theobjective acicular goethite particles.

A zinc compound is also preferably existent in a solution like ascorbicacid or a salt thereof before the acicular geothite particles or theacicular goethite nucleus particles are produced. A zinc compound may beadded to any of the aqueous ferrous salt solution, aqueous alkalihydroxide solution or aqueous alkali carbonate solution, ferrous saltreaction solution containing colloidal ferrous hydroxide oriron-containing colloidal precipitates, and the reaction solution whichis producing green rust. The order in which ascorbic acid or a saltthereof and a zinc compound are added to a solution is not restricted,and they may also be added simultaneously,

As the zinc compound, zinc sulfate, zinc chloride, zinc nitrate, etc.are usable. The amount of zinc compound added is 0.1 to 7.0 mol % basedon Fe in the ferrous salt reaction solution containing colloidal ferroushydroxide or iron-containing colloidal precipitates. If it is less than0.1 mol %, the effect of the zinc compound on the increase in the aspectratio (major axial diameter/minor axial diameter) of the aciculargoethite particles is insufficient. Even if it exceeds 7.0 mol %, it ispossible to obtain acicular goethite particles, but addition of any morethan is necessary is meaningless.

In the present invention, elements such as P, Al and Si, which aregenerally added in the process for producing goethite particles in orderto improve various properties of magnetic particles may be added. Inthis case, it is also possible to produce the objective aciculargoethite particles.

In order to grow the acicular goethite nucleus particles in the presentinvention, any method may be selected from the group consisting of amethod 1 blowing an oxygen-containing gas into the ferrous salt reactionsolution containing the acicular goethite nucleus particles whilemaintaining the pH at 3 to 6 after, if necessary, adding a ferrous saltthereto; a method 2 of blowing an oxygen-containing gas into the ferroussalt reaction solution containing the acicular goethite nucleusparticles at a pH of 8 to 10 which is adjusted by adding an aqueousalkali carbonate solution or an aqueous alkali carbonate and alkalihydroxide solution thereto after, if necessary, adding a ferrous saltthereto; and a method 3 of blowing an oxygen-containing gas into theferrous salt reaction solution containing the acicular goethite nucleusparticles at a pH of not less than 11 which is adjusted by adding anaqueous alkali hydroxide solution thereto after, if necessary, adding aferrous salt thereto.

The acicular goethite particles obtained by growing the aciculargoethite nucleus particles at a pH of 8 to 10 have a more uniformparticle size distribution, no inclusion of dendrites and a largeraspect ratio (major axial diameter/minor axial diameter).

In the present invention, an oxidization is carried out by blowing anoxygen-containing gas such as air into a solution under mechanicalstirring, if necessary.

The oxidizing reaction temperature in the present invention is nothigher than 80° C., preferably 30° to 55° C. when producing the aciculargoethite nucleus particles and growing the acicular goethite nucleusparticles by the methods 2 and 3, and not higher than 90° C., preferably30° to 90° C. when growing the acicular goethite nucleus particles bythe method 1. If the temperature is higher than the said temperatures,glanular magnetite particles are included in the acicular goethiteparticles.

The same reaction vessel may be used both for the reaction for producinggoethite nucleus particles and for the reaction for growing the goethitenucleus particles. It is also possible to obtain the objective goethiteparticles by using different reaction vessels for these reactions.

It is possible, if necessary, to coat the starting material particleswith elements such as P, Al and Si, which have a sintering preventingeffect, prior to the heat treatment in a reducing gas. The coatingtreatment prevents sintering particles and between particles, maintainsthe shape and the aspect ratio (major axial diameter/minor axialdiameter) of the starting material particles and facilitates theproduction of discrete magnetic iron oxide particles.

The oxidization in air according to the present invention is carried outat 200° to 500 ° C. by an ordinary method.

A Co-modification(Co-coating) of the magnetic iron oxide particles inthe present invention can be carried out by an ordinary method. Forexample, the Co-modification is carried out by dispersing the precursorparticles in an alkaline suspension containing cobalt hydroxide orcobalt hydroxide and ferrous hydroxide, and heat-treating thedispersion, as described in, e.g., Japanese Patent Publication Nos.52-24237 (1977), 52-24238 (1977), 52-36751 (1977) and 52-36863 (1977).

The cobalt hydroxide in the present invention is obtained by using anwater-soluble cobalt salt such as cobalt sulfide and cobalt chloride,and an aqueous alkali hydroxide solution such as an aqueous sodiumhydroxide solution and an aqueous potassium hydroxide solution.

The ferrous hydroxide in the present invention is obtained by using awater-soluble ferrous salt such as ferrous sulfide and ferrous chloride,and an aqueous alkali hydroxide solution such as an aqueous sodiumhydroxide solution and an aqueous potassium hydroxide solution.

The heat treatment for Co-modification is preferably carried out in annon-oxidizing atmosphere at a temperature of 50° to 100° C.

The temperature for Co-modification in the present invention concernsthe treating time. If the temperature is lower than 50° C., themagnetite particles or maghemite particles modified with Co or Co andFe²⁺ are difficult to produce, and even if they are produced, thetreating for a very long time is required.

The amount of the water-soluble cobalt salt used for Co-modification inthe present invention is 0.1 to 21.0 atomic % calculated as Co based onFe in the precursor particles. If it is less than 0.1 atomic %, thecoercive force of the acicular magnetite or maghemite particles producedis improved sufficiently. On the other hand, if it is more than 21.0atomic %, the coercive force distribution of the acicular magnetite ormaghemite particles produced is not sufficient.

The amount of the water-soluble ferrous salt used for Fe-modification inthe present invention is 0 to 35 atomic % calculated as Fe²⁺ based on Fein the precursor particles.

Almost the whole mount of water-soluble Co salt and water-solubleferrous salt added is utilized for the modification of the surfaces ofthe magnetic iron oxide particles.

In consideration of the coercive force and the coercive forcedistribution of the acicular magnetite particles or maghemite particles,the amount of water-soluble Co salt added is preferably 2.0 to 18.0atomic %.

According to the present invention, when an oxygen-containing gas isblown into a ferrous salt reaction solution containing colloidal ferroushydroxide or iron-containing colloidal precipitates which is obtained byreacting an aqueous ferrous salt solution with less than one equivalentof an aqueous alkali hydroxide solution, an aqueous alkali carbonatesolution, or an aqueous alkali hydroxide and alkali carbonate solutionbased on Fe²⁺ in the aqueous ferrous salt solution so as to oxidize theferrous hydroxide or colloidal iron-containing colloidal precipitatesand to produce acicular goethite particles through green rust, whileadding ascorbic acid or a salt thereof and, if necessary, a zinccompound to any of the solutions before the acicular goethite particlesare produced; or when an oxygen-containing gas is blown into a ferroussalt reaction solution containing colloidal ferrous hydroxide oriron-containing colloidal precipitates which is obtained by reacting anaqueous ferrous salt solution with less than one equivalent of anaqueous alkali hydroxide solution, an aqueous alkali carbonate solution,or an aqueous alkali hydroxide and alkali carbonate solution based onFe²⁺ in the aqueous ferrous salt solution so as to oxidize the colloidalferrous hydroxide or iron-containing colloidal precipitates and toproduce acicular goethite particles through green rust, the aciculargoethite particles produced through green rust are used as the aciculargoethite nucleus particles, and the acicular goethite nucleus particlesare grown so as to produce acicular goethite particles, while addingascorbic acid or a salt thereof and, if necessary, a zinc compound toany of the solutions before the acicular goethite nucleus particles areproduced, it is possible to obtain acicular goethite particles whichhave a uniform particle size distribution, which are substantially freeof dendrites and which have a large aspect ratio (major axial diameter).The acicular magnetic iron oxide particles obtained from the aciculargoethite particles as a starting material also have a uniform particlesize distribution, are free of dendrites and have a large aspect ratio(major axial diameter/minor axial diameter). The acicular magnetic ironoxide particles having these properties are also excellent in thecoercive force distribution.

It is considered to be because ascorbic acid or a salt thereof isexistent in a solution which is producing green rust, that aciculargoethite particles which have a uniform particle size distribution,which are substantially free of dendrites and which have a large aspectratio (major axial diameter/minor axial diameter) are obtained, as isobvious from later-described Comparative Examples in which the objectiveacicular goethite particles are not obtained in the case where ascorbicacid or a salt thereof is not existent in a solution which is producinggreen rust before the acicular goethite particles or the aciculargoethite nucleus particles are produced, or in the case where theacicular goethite particles are produced not through green rust in spiteof the existence of ascorbic acid or a salt thereof. The influence ofthe ascorbic acid or a salt thereof on the crystal habit forming processof the goethite particles is different between the reaction forproducing goethite particles at a pH of not less than 11 not throughgreen rust, in which the ascorbic acid or a salt thereof acts on thecolloidal aqueous hydroxide which is produced by reacting the aqueousferrous salt solution with the aqueous alkali hydroxide, and thereaction according to the present invention in which the ascorbic acidor a salt thereof acts on the green rust at a pH of 5 of 7.

As the amount of ascorbic acid or a salt thereof added is increased, theaspect ratio (major axial diameter/minor axial diameter) of the aciculargoethite particles has a tendency of increasing.

If a zinc compound is used together with an ascorbic acid or a saltthereof, it is possible to obtain acicular goethite particles having amore uniform particle size distribution, no inclusion of dendrites and alarger aspect ratio (major axial diameter/minor axial diameter) due tothe synergistic effect.

By adding ascorbic acid or a salt thereof, acicular goethite particleshaving an aspect ratio (major axial diameter/minor axial diameter) ofnot less than 20 are obtained, while by adding a zinc compound togetherwith an ascorbic acid or a salt thereof, acicular goethite particleshaving an aspect ratio (major axial diameter/minor axial diameter) ofnot less than 20, especially, not less than 25 are obtained.

The thus-obtained acicular goethite particles according to the presentinvention have a major axial diameter of 0.1 to 0.6 μm, preferably 0.12to 0.4 μm, an aspect ratio (major axial diameter/minor axial diameter)of not less than 20, preferably 25 to 40, and a particle sizedistribution (geometric standard deviation) of not less than 0.55,preferably not less than 0.6, more preferably not less than 0.7.

The acicular magnetite particles according to the present invention havea major axial diameter of 0.05 to 0.5 μm, preferably 0.05 to 0.4 μm, anaspect ratio (major axial diameter/minor axial diameter) of not lessthan 6.0, preferably 7.0 to 10.0 and a particle size distribution(geometrical standard deviation (σ_(g))) of not less than 0.5,preferably not less than 0.55.

The acicular maghemite particles according to the present invention havea major axial diameter of 0.05 to 0.5 μm, preferably 0.05 to 0.4 μm, anaspect ratio (major axial diameter/minor axial diameter) of not lessthan 6.0, preferably 7.0 to 10.0 and a particle size distribution(geometrical standard deviation(σ_(g))) of not less than 0.45,preferably not less than 0.5.

The acicular magnetite particles modified with Co or Co and Fe²⁺according to the present invention have a major axial diameter of 0.05to 0.5 μm, preferably 0.05 to 0.4 μm, an aspect ratio (major axialdiameter/minor axial diameter) of not less than 5.5, preferably 5.7 to9.0, a particle size distribution (geometrical standarddeviation(σ_(g))) of not less than 0.45, preferably not less than 0.50and contain 0.1 to 21 atomic % of Co based on Fe of the precursorparticles and 0 to 25 wt % of coated Fe²⁺ based on Fe in the precursorparticles.

The acicular maghemite particles modified with Co or Co and Fe²⁺according to the present invention have a major axial diameter of 0.05to 0.5 μm, preferably 0.05 to 0.4 μm, an aspect ratio (major axialdiameter/minor axial diameter) of not less than 5.5, preferably 5.7 to9.0 and a particle size distribution (geometrical standarddeviation(σ_(g))) of not less than 0.4, preferably not less than 0.5,and contains 0.1 to 21 atomic % of Co based on Fe of the precursorparticles and 0 to 25 atomic % of coated Fe²⁺ based on Fe in theprecursor particles.

According to the process for producing acicular goethite particles, itis possible to obtain acicular goethite particles which have a uniformparticle size distribution, which are free of dendrites and which have alarge aspect ratio (major axial diameter/minor axial diameter).

According to the process for producing the magnetic iron oxide particlesaccording to the present invention, it is possible to obtain acicularmagnetic iron oxide particles which have a uniform particle sizedistribution, which are free of dendrites and which have a large aspectratio (major axial diameter/minor axial diameter) and excellent coerciveforce distribution, so that they are suitable as magnetic particles forhigh-density, high-sensitivity and high-output recording.

[Examples]

The present invention will be explained in more detail while referringto the following non-limitative examples.

The major axial diameter and the aspect ratio (major axialdiameter/minor axial diameter) in each of the following examples andcomparative examples are expressed by the average values of the valuesobtained by measuring them in the electron micrographs.

The particle size distribution is expressed by the geometrical standarddeviation (σ_(g)). The major axial diameters of 350 particles weremeasured from electron micrographs (×120,000) and the actual major axialdiameters were calculated from the measured values. A cumulative mount(%) obtained from the number of the particles belonging to each regularinterval of the particle diameter was plotted in a logarithmicro-normalprobability paper with particle diameter (μm) as abscissa and cumulativeamount (%) as ordinate in accordance with a statistical method from theactual particle diameter and the number of the particles. A particlediameter (D₅₀) when the cumulative amount is 50% and a particle diameter(D₈₄.13) when the cumulative amount is 84.13%, were read out of theobtained log-normal distribution graph. The geometric standard deviation(σ_(g)) was found by dividing the particle diameter (D₅₀) by theparticle diameter (D₈₄.13) [σ_(g) =D₅₀ /D₈₄.13 ].

The magnetic characteristics and the coating film properties of themagnetic iron oxide particles were measured by using an "samplevibrating type magnetometer VSM-3S-15", (produced by Toei Kogyo K. K.)and applying an external magnetic field up to 5 KOe in case of acicularmagnetite particles and acicular maghemite particles, or an externalmagnetic field up to 10 KOe in case of acicular magnetic iron oxideparticles modified with Co or Co and Fe²⁺.

A sheet-like sample obtained by a method shown in later-describedExample 52 was used for measuring the squareness and the S.F.D. of thecoating film. The S.F.D. was measured by using a differentiation circuitof the above-described magnetometer to obtain the differentiation curveof the demagnetizing curve of the magnetism hysteresis curve, measuringthe half-width value of the curve and dividing the half-width by thecoercive force.

<Production of Acicular Goethite Particles> Examples 1 to 7 ComparativeExamples 1 to 3 Example 1

464 l of an aqueous ferrous sulfide solution containing 1.50 mol/l ofFe²⁺ and 228 l of 2.7-N aqueous NaOH solution (the content of NaOHcorresponds to 0.42 equivalent based on Fe²⁺ in the aqueous ferroussulfide solution) were mixed to produce at 40° C. at pH 6.8 an aqueousferrous sulfide solution containing Fe(OH)₂.

To the aqueous ferrous sulfide solution containing Fe(OH)₂, 0.1 l of anaqueous solution containing 23.8 g of ascorbic acid (corresponding to0.35 mol % based on Fe) was added, and an air was then blown thereintoat a rate of 800 l per minute at 40° C. for 6.8 hours, thereby producinggoethite nucleus particles. A part of the reaction solution wasextracted, filtered out, washed with water and dried by an ordinarymethod. The electron micrograph (×30000) of the particles obtained isshown in FIG. 1.

The acicular goethite particles produced had a major axial diameter of0.214 μm and an aspect ratio (major axial diameter/minor axial diameter)of 28, as shown in the FIG. 1. The particle size distribution wasuniform as expressed by a geometric standard deviation (σ_(g)) of 0.829,and no dendrites were included therein.

The goethite particles were used as acicular goethite nucleus particles,and 208 l of 7.0-N aqueous Na₂ CO₃ solution (the content of Na₂ CO₃corresponds to 1.8 equivalents based on Fe²⁺ in the residual aqueousferrous sulfide solution) was added to the aqueous ferrous sulfidesolution containing the acicular goethite nucleus particles (the amountof existent goethite nucleus particles corresponds to 42 mol % of theamount of goethite particles produced). Air was blown into the resultantsolution at a rate of 800 l per minute at 50° C. at pH 8.9 for 2.0hours, thereby producing goethite particles. The goethite particlesproduced were filtered out, washed with water and dried by an ordinarymethod.

The goethite particles produced were acicular particles having a majoraxial diameter of 0.267 μm and an aspect ratio (major axialdiameter/minor axial diameter) of 28, as shown in the electronmicrograph (×30000) in FIG. 2. The particle size distribution wasuniform as expressed by a geometric standard deviation (σ_(g)) of 0.817,and no dendrites were included therein.

Examples 2 to 7, Comparative Examples 1 to 3

Acicular goethite particles were produced in the same way as in Example1 except for varying the kind and amount of aqueous ferrous saltsolution used, the kind, concentration and amount of aqueous alkalinesolution, the kind and amount of ascorbic acid or a salt thereof used,the time for adding the ascorbic acid or a salt-thereof, the kind andmount of additional element and the reaction temperature in the processfor producing acicular goethite particles or acicular goethite nucleusparticles; and the amount of existent goethite nucleus particles, thekind, concentration and amount of aqueous alkaline solution, the kindand amount of additional element and the reaction temperature in theprocess for growing the goethite nuclear particles.

The main conditions for production and the properties of the goethiteparticles obtained are shown in Tables 1 and 2. In Comparative Examples2 and 3, acicular goethite nucleus particles were not produced throughgreen rust but acicular goethite particles were directly produced byblowing an oxygen-containing gas at a pH of not less than 11.

FIGS. 3 and 4 are electron micrographs (×30000) of the acicular goethitenucleus particles and the acicular goethite particles, respectively,obtained in Example 3, FIGS. 5 and 6 are electron micrographs (×30000)of the acicular goethite nucleus particles and the acicular goethiteparticles, respectively, obtained in Comparative Example 1, and FIGS. 7and 8 are electron micrographs (×30000) of the acicular goethiteparticles obtained in Comparative Examples 2 and 3, respectively.

As a result of observation through an electron microscope, it was provedthat any of the acicular goethite particles obtained in Examples 2 and 4to 7 had a uniform particle size distribution, no inclusion of dendritesand a large aspect ratio (major axial diameter/minor axial diameter).

The particle size distributions of the acicular goethite particlesobtained in Comparative Examples 1 and 3 were non-uniform and dendriteswere included therein, as shown in the electron micrographs in FIGS. 6and 8. The aspect ratio (major axial diameter/minor axial diameter) ofthe acicular goethite particles obtained in Comparative Example 2 wassmall.

<Production of Acicular Magnetite Particles> Examples 8 to 16Comparative Examples 4 to 6 Example 8

16.7 Kg of the paste of the acicular goethite particles (correspondingto about 5.0 Kg of acicular goethite particles) obtained in Example 1and filtered out and washed with water was suspended in 88 l of water.The pH of the suspension was 7.5. Thereafter, 750 ml of an aqueoussolution containing 75 g of sodium hexametaphosphate (corresponding to1.15 wt % calculated as PO₃ based on the acicular goethite particles)was added to the suspension, and the mixture was stirred for 30 minutes.The resultant suspension was filtered and dried to obtain aciculargoethite particles with the surfaces coated with a P compound. Thethus-obtained acicular goethite particles coated with a P compound wereheat-treated in air at 320° C., thereby obtaining acicular hematiteparticles coated with a P compound.

1000 g of the thus-obtained acicular hematite particles coated with a Pcompound were charged into a retort reducing vessel, and H₂ gas wasblown into the particles at a rate of 2 l per minute while rotating thevessel to reduce them at 360° C., thereby obtaining acicular magnetiteparticles coated with a P compound.

It was observed through an electron microscope that the acicularmagnetite particles coated with a P compound had an average major axialdiameter of 0.18 μm, an aspect ratio (major axial diameter/minor axialdiameter) of 7.9, that the particle size distribution was uniform asexpressed by a geometric standard deviation (σ_(g)) of 0.66 and that nodendrites were included. When the magnetic characteristics weremeasured, the coercive force (Hc) was 387 Oe and the saturationmagnetization (σ_(s)) was 83.8 emu/g.

Examples 9 to 16, Comparative Examples 4 to 6

Acicular magnetite particles were obtained in the same way as in Example8 except for varying the kind of the starting material, the execution oromission of the P-compound coating step, the execution or omission ofthe heat treatment in air and the heat-treating temperature.

The main conditions for production and the properties of the acicularmagnetite particles obtained are shown in Table 3. As a result ofobservation through an electron microscope, any of the acicularmagnetite particles obtained in Examples 9 to 16 proved to have auniform particle size distribution and no inclusion of dendrites.

<Production of Acicular Maghemite Particles> Examples 17 to 25Comparative Examples 7 to 9 Example 17

300 g of the acicular magnetite particles coated with a P compoundobtained in Example 8 were oxidized in air at 300° C. for 60 minutes toobtain acicular maghemite particles with the surfaces coated with a Pcompound.

It was observed through an electron microscope that the acicularmaghemite particles coated with a P compound had an average major axialdiameter of 0.17 μm, an aspect ratio (major axial diameter/minor axialdiameter) of 7.8, the particle size distribution was uniform asexpressed by a geometric standard deviation (σ_(g)) of 0.65 and nodendrites were included. When the magnetic characteristics weremeasured, the coercive force (Hc) was 354 Oe and the saturationmagnetization (σ_(s)) was 73.6 emu/g.

Examples 18 to 25, Comparative Examples 7 to 9

Acicular maghemite particles were obtained in the same way as in Example17 except for varying the kind of acicular magnetite particles. The mainconditions for production and the properties of the maghemite particlesobtained are shown in Table 4. As a result of observation through anelectron microscope, any of the acicular maghemite particles obtained inExamples 18 to 25 proved to have a uniform particle size distributionand no inclusion of dendrites.

<Production of Acicular Co-Modified Magnetite Particles> Examples 26 to38 Comparative Examples 10 to 12 Example 26

100 g of the acicular magnetite particles with the surfaces coated witha P compound obtained in Example 14 were charged into 1.0 l of waterwith 0.085 mol of cobalt and 0.179 mol of ferrous dissolved therein byusing cobalt sulfate and ferrous sulfate while preventing the inclusionof air as much as possible, and dispersed until the dispersion became afine slurry. Into the dispersion, 102 ml of 18-N aqueous NaOH solutionwas poured and water was further added so as to form 1.3 l of adispersion in which the hydroxyl concentration was 1.0 mol/l. Thetemperature of the dispersion was raised to 100° C. and it was stirredfor 5 hours. Thereafter, the slurry was taken out, washed with water,filtered out and dried at 60° C. to obtain acicular Co-modifiedmagnetite particles.

As a result of observation through an electron microscope, it was provedthat the acicular magnetite particles modified with Co and Fe²⁺ obtainedhad the same shape and the particle size as the precursor particles,namely, the acicular magnetite particles with the surfaces coated with aP compound, an average major axial diameter of 0.28 μm and an aspectratio (major axial diameter/minor axial diameter) of 7.1. The particlesize distribution was uniform as expressed by a geometric standarddeviation (σ_(g)) of 0.56. When the magnetic characteristics weremeasured, the coercive force (Hc) was 803 Oe and the saturationmagnetization (σ_(s)) was 83.1 emu/g.

Examples 27 to 38, Comparative Examples 10 to 12

Acicular magnetite particles modified by Co or Co and Fe²⁺ were obtainedin the same way as in Example 26 except for varying the kind ofprecursor particles, the amounts of Co added, Fe²⁺ added and NaOH addedunder conditions that the mount of precursor magnetite particles was 100g and the whole volume of the dispersion was 1.3 l.

The main conditions for production and the properties of the particlesobtained are shown in Table 5.

<Production of Acicular Co-Modified Maghemite Particles> Examples 39 to51 Comparative Examples 13 to 15 Example 39

100 g of acicular maghemite particles with the surfaces coated with a Pcompound obtained in Example 23 were charged into 1.0 l of water with0.085 mol of cobalt and 0.179 mol of ferrous dissolved therein by usingcobalt sulfate and ferrous sulfate while preventing the inclusion of airas much as possible, and dispersed until the dispersion became a fineslurry. Into the dispersion, 102 ml of 18-N aqueous NaOH solution waspoured and water was further added so as to form 1.3 l of dispersion inwhich the hydroxyl concentration was 1.0 mol/l. The temperature of thedispersion was raised to 100° C. and it was stirred for 5 hours.Thereafter, the slurry was taken out, washed with water, filtered outand dried at 60° C. to obtain acicular Co-modified maghemite particles.

As a result of observation through an electron microscope, it was provedthat the acicular maghemite particles modified with Co and Fe²⁺ obtainedhad the same shape and the particle size as the precursor particles,namely, the acicular maghemite particles with the surfaces coated with aP compound, an average major axial diameter of 0.27 μm and an aspectratio (major axial diameter/minor axial diameter) of 7.0. The particlesize distribution was uniform as expressed by a geometric standarddeviation (σ_(g)) of 0.56. When the magnetic characteristics weremeasured, the coercive force (Hc) was 779 Oe and the saturationmagnetization (σ_(s)) was 76.3 emu/g.

Examples 40 to 51, comparative Examples 13 to 15

Acicular maghemite particles modified by Co or Co and Fe²⁺ were obtainedin the same way as in Example 39 except for varying the kind of theprecursor particles, the amounts of Co added, Fe(II) added and NaOHadded and the treating temperature and time under conditions that theamount of precursor acicular maghemite particles was 100 g and the wholevolume of the dispersion was 1.3 l.

The main conditions for production and the properties of the particlesobtained are shown in Table 6.

<Production of Magnetic Tape> Examples 52 to 95 Comparative Examples 16to 27 Example 52

A magnetic tape was produced in the following manner. A magnetic coatingwas prepared by charging the acicular magnetic iron oxide particles withthe surfaces coated with a P compound obtained in Example 8, the resinand the solvents described below into a 140-cc glass bottle in thefollowing ratio and mixing and dispersing the above materials by a paintconditioner for 2 hours. The magnetic coating was applied to apolyethylene terephthalate film (25 μm in thickness) to a thickness of40 μm by an applicator, and the film was then oriented and dried in amagnetic field of 1450 Gauss.

    ______________________________________                                        Glass beads 1.5 mm in diameter                                                                           100 g                                              Acicular magnetite particles                                                                             15 g                                               Toluene                    5.6 g                                              Phosphate ester (GAFAC RE-610, produced                                                                  0.6 g                                              by Toho Chemical Industrial Co., Ltd.)                                        Lecithin                   0.6 g                                              Vinyl chloride-vinyl acetate                                                                             3.75 g                                             copolymer resin (Vinilite VAGH                                                produced by Union Carbide)                                                    Butadiene acrylonitrile    0.75 g                                             rubber (Hycar 1432 J, produced by                                             Japanese Geon Co., Ltd.)                                                      Mixed solution of Methyl isobutyl keton,                                                                 40.5 g                                             methyl ethyl ketone and toluene (3:1:1)                                       ______________________________________                                    

The magnetic tape produced had and an S.F.D. of 0.50, a coercive force(Hc) of 355 Oe, a residual flux density (Br) of 1660 Gauss and asquareness (Br/Bm) of 0.81.

Examples 53 to 95, Comparative Examples 16 to 27

Magnetic tapes were produced in the same way as in Example 52 except forvarying the kind of magnetic particles. The acicular maghemite particleswere oriented in a magnetic field of 1450 Gauss and the Co-modifiedmagnetic iron oxide particles were oriented in a magnetic field of 1900Gauss. The properties of the magnetic tapes obtained are shown in Tables7 to 10.

                                      TABLE 1                                     __________________________________________________________________________            Production of goethite nucleus particles                                      Aqueous ferrous salt                                                          solution         Aqueous alkaline solution                            Examples and Fe.sup.2+                Amount                                  Comparativge concentration                                                                        Amount    Concentration                                                                             CO.sub.3 /Fe or 2OH/Fe              Examples                                                                              Kind (mol/l)                                                                              (l)  Kind (N)     (l) (equivalent ratio)                  __________________________________________________________________________    Example 1                                                                             FeSO.sub.4                                                                         1.50   464  NaOH 2.7     228 0.42                                Example 2                                                                             FeSO.sub.4                                                                         1.50   464  NaOH 2.7     228 0.42                                Example 3                                                                             FeSO.sub.4                                                                         1.50   464  NaOH 2.7     228 0.42                                Example 4                                                                             FeSO.sub.4                                                                         1.50   420  NaOH 1.5     380 0.45                                Example 5                                                                             FeCl.sub.2                                                                         1.50   373  K.sub.2 CO.sub.3                                                                   1.7     327 0.50                                Example 6                                                                             FeSO.sub.4                                                                         1.50   377  NaOH 1.4      87 0.36                                                         Na.sub.2 CO.sub.3                                                                  1.4     204                                     Example 7                                                                             FeSO.sub.4                                                                         1.50   464  KOH  3.0     205 0.42                                Comparative                                                                           FeSO.sub.4                                                                         1.50   464  NaOH 2.7     228 0.42                                Example 1                                                                     Comparative                                                                           FeSO.sub.4                                                                         1.50   464  NaOH 7.4     436 2.3                                 Example 2                                                                     Comparative                                                                           FeSO.sub.4                                                                         1.50   180  NaOH 1.8     720 2.4                                 Example 3                                                                     __________________________________________________________________________            Production of goethite nucleus particles                              Examples and                                                                          Ascorbic acid or salt thereof                                                                Additional metal  Reaction                                                                             Reaction                      Comparativge Amount                                                                             Time for                                                                              Amount                                                                             Time for                                                                           pH for                                                                             temperature                                                                          time                          Examples                                                                              Kind (mol %)                                                                            addition*                                                                          Kind                                                                             (mol %)                                                                            addition*                                                                          reaction                                                                           (°C.)                                                                         (hr)                          __________________________________________________________________________    Example 1                                                                             Ascorbic                                                                           0.35 A    -- --   --   6.8  40     6.8                                   acid                                                                  Example 2                                                                             Ascorbic                                                                           0.30 D    P  0.23 A    6.8  40     7.5                                   acid                                                                  Example 3                                                                             Ascorbic                                                                           0.35 A    Zn 1.0  A    6.8  40     8.1                                   acid                                                                  Example 4                                                                             Sodium                                                                             0.35 B    -- --   --   6.8  40     6.6                                   ascorbate                                                             Example 5                                                                             Sodium                                                                             0.35 C    Al 1.0  --   6.8  40     6.4                                   ascorbate                                                             Example 6                                                                             Ascorbic                                                                           0.12 C    P  0.24 B    6.5  40     2.7                                   acid                                                                  Example 7                                                                             Ascorbic                                                                           0.15 D    -- --   C    6.7  40     3.2                                   acid                                                                  Comparative                                                                           --   --   --   -- --   --   6.8  40     14.7                          Example 1                                                                     Comparative                                                                           Ascorbic                                                                           0.35 A    -- --   --   13.0 40     27.6                          Example 2                                                                             acid                                                                  Comparative                                                                           --   --   --   -- --   --   12.8 40     8.8                           Example 3                                                                     __________________________________________________________________________     *A: Add to aqueous ferrous salt solution.                                     B: Add to aqueous alkali hydroxide or aqueous alkali carbonate.               C: Add to ferrous salt reaction solution containing colloidal ferrous         hydroxide, or ironcontaining colloidal precipitates.                          D: Add to ferrous salt reaction solution containing green rust.          

                                      TABLE 2                                     __________________________________________________________________________            Goethite nucleus particles                                                                         Growing goethite nucleus particles                                    Aspect ratio                                                                          Amount of                                                Particle                                                                             Major (major axial                                                                          goethite                                         Examples and                                                                          size   axial diameter/minor                                                                        nucleus                                                                             Aqueous alkaline solution                  Comparativge                                                                          distribution                                                                         diameter                                                                            axial   particles   Concentration                        Examples                                                                              (σg)                                                                           (μm)                                                                             diameter)                                                                             (mol %)                                                                             Kind  (N)                                  __________________________________________________________________________    Example 1                                                                             0.829  0.214 28      42    NaCO.sub.3                                                                          7.0                                  Example 2                                                                             0.810  0.197 32      42    NaCO.sub.3                                                                          7.0                                  Example 3                                                                             0.804  0.230 33      42    NaCO.sub.3                                                                          7.0                                  Example 4                                                                             0.827  0.226 25      45    NaOH  13.0                                 Example 5                                                                             0.815  0.210 27      50    NaOH  8.1                                  Example 6                                                                             0.818  0.263 28      36    NaOH  7.0                                                                     NaCO.sub.3                                                                          7.0                                  Example 7                                                                             0.830  0.161 25      42    NaCO.sub.3                                                                          7.0                                  Comparative                                                                           0.486  0.413  9      42    NaCO.sub.3                                                                          7.0                                  Example 1                                                                     Comparative                                                                           --     --    --      --    --    --                                   Example 2                                                                     Comparative                                                                           --     --    --      --    --    --                                   Example 3                                                                     __________________________________________________________________________            Growing goethite nucleus particles                                            Aqueous alkaline                                                              solution                Goethite particles                                    Amount                            Aspect ratio                                   CO.sub.3 /Fe or      Particle                                                                           Major                                                                              (major axial                        Examples and                                                                             2OH/Fe     Reaction                                                                           Reaction                                                                           size axial                                                                              diameter/                           Comparativge                                                                             (equivalent                                                                         pH for                                                                             tempera-                                                                           time distribu-                                                                          diameter                                                                           minor axial                         Examples                                                                              (l)                                                                              ratio)                                                                              reaction                                                                           ture (°C.)                                                                  (hr) tion (σg)                                                                    (μm)                                                                            diameter                            __________________________________________________________________________    Example 1                                                                             208                                                                              1.8   8.9  50   2.0  0.817                                                                              0.267                                                                              28                                  Example 2                                                                             208                                                                              1.8   8.9  50   3.2  0.801                                                                              0.246                                                                              33                                  Example 3                                                                             208                                                                              1.8   8.9  50   4.0  0.766                                                                              0.288                                                                              35                                  Example 4                                                                              53                                                                              1.0   4.5  80   8.7  0.742                                                                              0.330                                                                              25                                  Example 5                                                                             200                                                                              2.9   13.1 50   12.4 0.769                                                                              0.386                                                                              28                                  Example 6                                                                              62                                                                              2.0   8.7  52   3.1  0.803                                                                              0.325                                                                              27                                          145                                                                   Example 7                                                                             231                                                                              2.0   8.9  50   1.5  0.821                                                                              0.201                                                                              25                                  Comparative                                                                           208                                                                              1.8   8.9  50   12.9 0.489                                                                              0.523                                                                              10                                  Example 1                                                                     Comparative                                                                           -- --    --   --   --   0.518                                                                              0.350                                                                              11                                  Example 2                                                                     Comparative                                                                           -- --    --   --   --   0.544                                                                              0.261                                                                               9                                  Example 3                                                                     __________________________________________________________________________

                                      TABLE 3                                     __________________________________________________________________________           Acicular                                                                      goethite                                                                      particles                                                                            Coating   Heating   Acicular magnetite particles                       (Example                                                                             with P compound                                                                         temper-                                                                            Reducing                                                                           Major                                                                              Aspect ratio                                                                          Particle                                                                           Coercive                                                                           Saturation           Examples &                                                                           No. &        A-  ature                                                                              tem- axial                                                                              (major axial                                                                          size force                                                                              magnetiza-           Comparative                                                                          Comparative  mount                                                                             in air                                                                             perature                                                                           diameter                                                                           diameter/minor                                                                        distribu-                                                                          Hc   tion                                                                          σ.sub.s        Examples                                                                             Example No.)                                                                         Kind  (wt %)                                                                            (°C.)                                                                       (°C.)                                                                       (μm)                                                                            axial diameter)                                                                       tion (σg)                                                                    (Oe) (emu/g)              __________________________________________________________________________    Example 8                                                                            Example 1                                                                            Sodium                                                                              1.15                                                                              320  360  0.18 7.9     0.66 387  83.8                               hexameta-                                                                     phosphate                                                       Example 9                                                                            Example 2                                                                            Sodium                                                                              1.15                                                                              320  360  0.17 8.2     0.65 393  80.1                               hexameta-                                                                     phosphate                                                       Example 10                                                                           Example 3                                                                            Sodium                                                                              1.15                                                                              320  360  0.19 8.7     0.60 398  83.3                               hexameta-                                                                     phosphate                                                       Example 11                                                                           Example 4                                                                            --    --  320  360  0.26 7.0     0.58 403  84.7                 Example 12                                                                           goethite                                                                             Sodium                                                                              1.15                                                                              320  360  0.15 7.4     0.57 382  83.0                        nucleus                                                                              hexameta-                                                              particles of                                                                         phosphate                                                              Example 4                                                              Example 13                                                                           Example 4                                                                            Sodium                                                                              1.15                                                                              650  360  0.29 7.6     0.59 426  83.0                               hexameta-                                                                     phosphate                                                       Example 14                                                                           Example 5                                                                            Sodium                                                                              1.15                                                                              320  360  0.30 7.9     0.61 434  81.1                               hexameta-                                                                     phosphate                                                       Example 15                                                                           Example 6                                                                            Sodium                                                                              1.15                                                                              320  360  0.29 7.8     0.66 425  80.0                               hexameta-                                                                     phosphate                                                       Example 16                                                                           Example 7                                                                            Sodium                                                                              1.15                                                                              320  360  0.14 7.5     0.67 366  83.2                               hexameta-                                                                     phosphate                                                       Comparative                                                                          Comparative                                                                          Sodium                                                                              1.15                                                                              320  360  0.32 5.6     0.31 396  83.9                 Example 4                                                                            Example 1                                                                            hexameta-                                                                     phosphate                                                       Comparative                                                                          Comparative                                                                          Sodium                                                                              1.15                                                                              320  360  0.27 4.9     0.36 367  83.8                 Example 5                                                                            Example 2                                                                            hexameta-                                                                     phosphate                                                       Comparative                                                                          Comparative                                                                          Sodium                                                                              1.15                                                                              320  360  0.12 4.7     0.39 323  84.3                 Example 6                                                                            Example 3                                                                            hexameta-                                                                     phosphate                                                       __________________________________________________________________________

                                      TABLE 4                                     __________________________________________________________________________           Acicular mag-                                                                         Acicular maghemite particles                                          netite particles                                                                            Aspect ratio           Saturation                        Examples &                                                                           (Example No. &                                                                        Major axial                                                                         (major axial                                                                          Particle size                                                                        Coercive force                                                                        magnetization                     Comparative                                                                          Comparative                                                                           diameter                                                                            diameter/minor                                                                        distribution                                                                         Hc      σ.sub.s                     Examples                                                                             Example No.)                                                                          (μm)                                                                             axial diameter)                                                                       (σg)                                                                           (Oe)    (emu/g)                           __________________________________________________________________________    Example 17                                                                           Example 8                                                                             0.17  7.8     0.65   354     73.6                              Example 18                                                                           Example 9                                                                             0.15  8.1     0.54   367     69.8                              Example 19                                                                           Example 10                                                                            0.18  8.6     0.58   370     73.2                              Example 20                                                                           Example 11                                                                            0.25  6.9     0.57   371     74.8                              Example 21                                                                           Example 12                                                                            0.14  7.3     0.57   355     72.9                              Example 22                                                                           Example 13                                                                            0.27  7.7     0.58   390     73.0                              Example 23                                                                           Example 14                                                                            0.29  7.7     0.60   403     71.4                              Example 24                                                                           Example 15                                                                            0.27  7.7     0.65   398     70.0                              Example 25                                                                           Example 16                                                                            0.13  7.4     0.67   330     73.5                              Comparative                                                                          Comparative                                                                           0.31  5.4     0.30   365     74.0                              Example 7                                                                            Example 4                                                              Comparative                                                                          Comparative                                                                           0.26  4.8     0.35   338     73.9                              Example 8                                                                            Example 5                                                              Comparative                                                                          Comparative                                                                           0.11  4.6     0.38   280     74.5                              Example 9                                                                            Example 6                                                              __________________________________________________________________________

                                      TABLE 5                                     __________________________________________________________________________                 Production                                                                    of acicular magnetite particles modified                                                           Acicular magnetite                          Precursor    with Co or Co and Fe.sup.2+                                                                        particles modified with Co or Co and                                          Fe.sup.2+                                   Examples &                                                                          particles (Ex-                                                                       Amount                                                                             Amount                                                                             Amount     Major                                                                              Aspect ratio                                                                          Particle  Saturation           Com-  ample No. &                                                                          of Co                                                                              of Fe.sup.2+                                                                       of caustic                                                                          Temper-                                                                            axial                                                                              (major axial di-                                                                      size Coercise                                                                           magnetiza-           parative                                                                            Comparative                                                                          added                                                                              added                                                                              alkali                                                                              ature                                                                              diameter                                                                           ameter/minor                                                                          distribu-                                                                          force                                                                              tion                                                                          σ.sub.s        Examples                                                                            Example No.)                                                                         (mol)                                                                              (mol)                                                                              added (ml)                                                                          (°C.)                                                                       (μm)                                                                            axial diameter)                                                                       tion (σg)                                                                    (Oe) (emu/g)              __________________________________________________________________________    Example 26                                                                          Example 14                                                                           0.085                                                                              0.179                                                                              102   100  0.28 7.1     0.56 803  83.1                 Example 27                                                                          Example 14                                                                            0.0509                                                                            0.179                                                                               98   100  0.28 7.2     0.56 705  84.5                 Example 28                                                                          Example 14                                                                            0.0509                                                                            0.179                                                                              170   100  0.28 7.2     0.57 735  83.5                 Example 29                                                                          Example 14                                                                            0.0509                                                                             0.1074                                                                            162   100  0.27 7.4     0.58 692  83.6                 Example 30                                                                          Example 14                                                                            0.0509                                                                            --   150   100  0.27 7.6     0.59 650  79.1                 Example 31                                                                          Example 8                                                                            0.085                                                                              0.179                                                                              102   100  0.16 6.4     0.64 850  85.7                 Example 32                                                                          Example 9                                                                            0.085                                                                              0.179                                                                              102   100  0.14 6.8     0.63 845  82.7                 Example 33                                                                          Example 10                                                                           0.085                                                                              0.179                                                                              102   100  0.16 7.1     0.59 843  85.5                 Example 34                                                                          Example 11                                                                           0.085                                                                              0.179                                                                              102   100  0.23 6.0     0.56 824  86.8                 Example 35                                                                          Example 12                                                                           0.085                                                                              0.179                                                                              102   100  0.13 6.3     0.54 820  85.1                 Example 36                                                                          Example 13                                                                           0.085                                                                              0.179                                                                              102   100  0.27 6.7     0.56 820  85.2                 Example 37                                                                          Example 15                                                                           0.085                                                                              0.179                                                                              102   100  0.26 7.0     0.64 807  82.4                 Example 38                                                                          Example 16                                                                           0.085                                                                              0.179                                                                              102   100  0.11 6.1     0.65 856  85.4                 Compara-                                                                            Comparative                                                                          0.085                                                                              0.179                                                                              102   100  0.29 5.2     0.30 795  85.9                 tive  Example 4                                                               Example 10                                                                    Compara-                                                                            Comparative                                                                          0.085                                                                              0.179                                                                              102   100  0.25 4.6     0.34 797  86.7                 tive  Example 6                                                               Example 11                                                                    Compara-                                                                            Comparative                                                                          0.085                                                                              0.179                                                                              102   100  0.10 4.3     0.38 780  86.0                 tive  Example 6                                                               Example 12                                                                    __________________________________________________________________________

                                      TABLE 6                                     __________________________________________________________________________                 Production                                                                    of acicular maghemite particles modified                                                           Acicular maghemite                          Precursor    with Co or Co and Fe.sup.2+                                                                        particles modified with Co or Co and                                          Fe.sup.2+                                   Examples &                                                                          particles (Ex-                                                                       Amount                                                                             Amount                                                                             Amount     Major                                                                              Aspect ratio                                                                          Particle  Saturation           Com-  ample No. &                                                                          of Co                                                                              of Fe.sup.2+                                                                       of caustic                                                                          Temper-                                                                            axial                                                                              (major axial di-                                                                      size Coercise                                                                           magnetiza-           parative                                                                            Comparative                                                                          added                                                                              added                                                                              alkali                                                                              ature                                                                              diameter                                                                           ameter/minor                                                                          distribu-                                                                          force                                                                              tion                                                                          σ.sub.s        Examples                                                                            Example No.)                                                                         (mol)                                                                              (mol)                                                                              added (ml)                                                                          (°C.)                                                                       (μm)                                                                            axial diameter)                                                                       tion (σg)                                                                    (Oe) (emu/g)              __________________________________________________________________________    Example 39                                                                          Example 23                                                                           0.085                                                                              0.179                                                                              102   100  0.27 7.0     0.56 779  76.3                 Example 40                                                                          Example 23                                                                            0.0509                                                                            0.179                                                                               98   100  0.28 7.0     0.56 685  77.4                 Example 41                                                                          Example 23                                                                            0.0509                                                                            0.179                                                                              170   100  0.27 7.1     0.57 714  77.6                 Example 42                                                                          Example 23                                                                            0.0509                                                                             0.1074                                                                            162   100  0.26 7.2     0.58 670  75.4                 Example 43                                                                          Example 23                                                                            0.0509                                                                            --   150   100  0.25 7.5     0.59 626  69.8                 Example 44                                                                          Example 17                                                                           0.085                                                                              0.179                                                                              102   100  0.15 6.2     0.62 831  78.5                 Example 45                                                                          Example 18                                                                           0.085                                                                              0.179                                                                              102   100  0.12 6.6     0.52 822  75.0                 Example 46                                                                          Example 19                                                                           0.085                                                                              0.179                                                                              102   100  0.15 6.9     0.56 820  78.1                 Example 47                                                                          Example 20                                                                           0.085                                                                              0.179                                                                              102   100  0.22 5.8     0.54 802  79.2                 Example 48                                                                          Example 21                                                                           0.085                                                                              0.179                                                                              102   100  0.11 6.2     0.54 802  77.6                 Example 49                                                                          Example 22                                                                           0.085                                                                              0.179                                                                              102   100  0.25 6.6     0.56 798  78.1                 Example 50                                                                          Example 24                                                                           0.085                                                                              0.179                                                                              102   100  0.25 6.8     0.63 785  75.1                 Example 51                                                                          Example 25                                                                           0.085                                                                              0.179                                                                              102   100  0.09 6.0     0.65 829  78.1                 Compara-                                                                            Comparative                                                                          0.085                                                                              0.179                                                                              102   100  0.27 5.3     0.29 755  79.5                 tive  Example 7                                                               Example 13                                                                    Compara-                                                                            Comparative                                                                          0.085                                                                              0.179                                                                              102   100  0.24 4.5     0.34 750  79.4                 tive  Example 8                                                               Example 14                                                                    Compara-                                                                            Comparative                                                                          0.085                                                                              0.179                                                                              102   100  0.09 4.3     0.37 747  79.2                 tive  Example 9                                                               Example 15                                                                    __________________________________________________________________________

                                      TABLE 7                                     __________________________________________________________________________           Magnetic                                                                      particles                                                                             Tape properties                                                Examples &                                                                           (Example No. &    Coercive force                                                                        Residual flux                                Comparative                                                                          Comparative Squareness                                                                          Hc      density Br                                   Examples                                                                             Example No.)                                                                          S.F.D.                                                                            (Br/Bm)                                                                             (Oe)    (Gauss)                                      __________________________________________________________________________    Example 52                                                                           Example 8                                                                             0.50                                                                              0.81  355     1610                                         Example 53                                                                           Example 9                                                                             0.52                                                                              0.81  368     1570                                         Example 54                                                                           Example 10                                                                            0.48                                                                              0.83  369     1620                                         Example 55                                                                           Example 11                                                                            0.45                                                                              0.78  370     1510                                         Example 56                                                                           Example 12                                                                            0.54                                                                              0.79  353     1560                                         Example 57                                                                           Example 13                                                                            0.44                                                                              0.83  392     1610                                         Example 58                                                                           Example 14                                                                            0.43                                                                              0.86  395     1580                                         Example 59                                                                           Example 15                                                                            0.42                                                                              0.85  394     1550                                         Example 60                                                                           Example 16                                                                            0.56                                                                              0.78  340     1520                                         Comparative                                                                          Comparative                                                                           0.67                                                                              0.72  362     1390                                         Example 16                                                                           Example 4                                                              Comparative                                                                          Comparative                                                                           0.61                                                                              0.66  335     1260                                         Example 17                                                                           Example 5                                                              Comparative                                                                          Comparative                                                                           0.75                                                                              0.68  292     1340                                         Example 18                                                                           Example 6                                                              __________________________________________________________________________

                                      TABLE 8                                     __________________________________________________________________________           Magnetic                                                                      particles                                                                             Tape properties                                                Examples &                                                                           (Example No. &    Coercive force                                                                        Residual flux                                Comparative                                                                          Comparative Squareness                                                                          Hc      density Br                                   Examples                                                                             Example No.)                                                                          S.F.D.                                                                            (Br/Bm)                                                                             (Oe)    (Gauss)                                      __________________________________________________________________________    Example 61                                                                           Example 17                                                                            0.40                                                                              0.84  330     1440                                         Example 62                                                                           Example 18                                                                            0.41                                                                              0.84  345     1310                                         Example 63                                                                           Example 19                                                                            0.39                                                                              0.86  348     1410                                         Example 64                                                                           Example 20                                                                            0.36                                                                              0.81  350     1480                                         Example 65                                                                           Example 21                                                                            0.44                                                                              0.83  353     1360                                         Example 66                                                                           Example 22                                                                            0.35                                                                              0.85  369     1400                                         Example 67                                                                           Example 23                                                                            0.33                                                                              0.88  378     1370                                         Example 68                                                                           Example 24                                                                            0.32                                                                              0.88  377     1320                                         Example 69                                                                           Example 25                                                                            0.45                                                                              0.79  310     1280                                         Example 19                                                                           Example 7                                                                             0.58                                                                              0.75  332     1210                                         Example 20                                                                           Example 8                                                                             0.70                                                                              0.69  305     1100                                         Example 21                                                                           Example 9                                                                             0.67                                                                              0.71  258     1160                                         Example 70                                                                           Example 26                                                                            0.46                                                                              0.86  831     1620                                         Example 71                                                                           Example 27                                                                            0.43                                                                              0.86  730     1650                                         Example 72                                                                           Example 28                                                                            0.42                                                                              0.87  764     1645                                         Example 73                                                                           Example 29                                                                            0.39                                                                              0.88  713     1670                                         Example 74                                                                           Example 30                                                                            0.37                                                                              0.89  681     1595                                         Example 76                                                                           Example 31                                                                            0.53                                                                              0.81  870     1570                                         Example 76                                                                           Example 32                                                                            0.55                                                                              0.80  863     1500                                         Example 77                                                                           Example 33                                                                            0.51                                                                              0.83  865     1610                                         Example 78                                                                           Example 34                                                                            0.49                                                                              0.79  840     1555                                         Example 79                                                                           Example 35                                                                            0.57                                                                              0.78  839     1510                                         Example 80                                                                           Example 36                                                                            0.46                                                                              0.83  842     1600                                         Example 81                                                                           Example 37                                                                            0.45                                                                              0.84  829     1570                                         Example 82                                                                           Example 38                                                                            0.58                                                                              0.77  871     1490                                         Comparative                                                                          Comparative                                                                           0.69                                                                              0.71  710     1380                                         Example 22                                                                           Example 10                                                             Comparative                                                                          Comparative                                                                           0.65                                                                              0.65  805     1290                                         Example 23                                                                           Example 11                                                             Comparative                                                                          Comparative                                                                           0.77                                                                              0.67  793     1310                                         Example 24                                                                           Example 12                                                             __________________________________________________________________________

                                      TABLE 10                                    __________________________________________________________________________           Magnetic                                                                      particles                                                                             Tape properties                                                Examples &                                                                           (Example No. &    Coercive force                                                                        Residual flux                                Comparative                                                                          Comparative Squareness                                                                          Hc      density Br                                   Examples                                                                             Example No.)                                                                          S.F.D.                                                                            (Br/Bm)                                                                             (Oe)    (Gauss)                                      __________________________________________________________________________    Example 83                                                                           Example 39                                                                            0.36                                                                              0.87  807     1540                                         Example 84                                                                           Example 40                                                                            0.35                                                                              0.88  710     1580                                         Example 85                                                                           Example 41                                                                            0.34                                                                              0.88  740     1590                                         Example 86                                                                           Example 42                                                                            0.31                                                                              0.90  690     1580                                         Example 87                                                                           Example 43                                                                            0.30                                                                              0.90  650     1460                                         Example 88                                                                           Example 44                                                                            0.43                                                                              0.82  852     1495                                         Example 89                                                                           Example 45                                                                            0.44                                                                              0.82  843     1430                                         Example 90                                                                           Example 46                                                                            0.41                                                                              0.85  846     1540                                         Example 91                                                                           Example 47                                                                            0.38                                                                              0.82  824     1510                                         Example 92                                                                           Example 48                                                                            0.47                                                                              0.80  816     1440                                         Example 93                                                                           Example 49                                                                            0.38                                                                              0.85  820     1540                                         Example 94                                                                           Example 50                                                                            0.35                                                                              0.86  712     1500                                         Example 95                                                                           Example 51                                                                            0.47                                                                              0.79  848     1430                                         Comparative                                                                          Comparative                                                                           0.56                                                                              0.74  770     1360                                         Example 25                                                                           Example 13                                                             Comparative                                                                          Comparative                                                                           0.68                                                                              0.67  757     1210                                         Example 26                                                                           Example 14                                                             Comparative                                                                          Comparative                                                                           0.69                                                                              0.70  760     1290                                         Example 27                                                                           Example 16                                                             __________________________________________________________________________

What is claimed is:
 1. A process for producing acicular goethiteparticles having an aspect ratio of not less than 20 comprising the stepof blowing an oxygen-containing gas into a ferrous salt reactionsolution containing either colloidal ferrous hydroxide which is obtainedby reacting an aqueous ferrous salt solution with less than oneequivalent of an aqueous hydroxide solution based on Fe²⁺ in saidaqueous ferrous salt solution or iron-containing colloidal precipitateswhich are obtained by reacting an aqueous ferrous salt solution withless than one equivalent of an aqueous alkali carbonate solution or anaqueous hydroxide and carbonate solution based on Fe²⁺ in said aqueousferrous salt solution, at a temperature not higher than 80° C. so as tooxidize said colloidal ferrous hydroxide or iron-containing colloidalprecipitates and to produce acicular goethite particles through greenrust which is produced at a pH of 5 to 7,wherein (a) from 0.01 to 5.0mol % ascorbic acid or a salt thereof calculated as ascorbic acid basedon Fe in the ferrous salt reaction solution and lb) at least onecompound selected from the group consisting of compounds containing P,Si and Al are present in the solution before said acicular goethiteparticles are produced.
 2. The process according to claim 1, wherein (c)0.1 to 7.0 mol % of a zinc compound based on Fe in the ferrous saltreaction solution is present in said solution in addition to (a) and(b).
 3. A process for producing acicular magnetic iron oxide particlescomprising the step of:heat-treating in a reducing gas the aciculargoethite particles obtained by the process according to claim 1 or claim2, thereby producing acicular magnetite particles.
 4. A process forproducing acicular magnetic iron oxide particles comprising the stepsof:heat-treating the acicular goethite particles obtained by the processaccording to claim 1 or 2 at 300° to 700° C., thereby producing acicularhematite particles; and heat-treating the acicular hematite particles ina reducing gas, thereby producing acicular magnetite particles.
 5. Theprocess according to claim 3 or 4, further comprising an additional stepof oxidizing the acicular magnetite particles, thereby producingacicular maghemite particles.
 6. A process for producing acicularmagnetic iron oxide particles comprising the steps of:dispersing theacicular magnetite particles obtained according to claim 3 or claim 4 oracicular maghemite particles obtained according to claim 5 as precursorparticles in an alkaline suspension containing either cobalt hydroxideor cobalt hydroxide and ferrous hydroxide wherein said suspension has aCo content of 0.1 to 21.0 atomic % based on Fe of said precursorparticles; and heat-treating at a temperature of 50° to 100° C. theresultant aqueous dispersion, thereby obtaining acicular magnetiteparticles or acicular maghemite particles modified with Co or Co andFe²⁺.
 7. A process for producing acicular goethite particles having anaspect ratio of not less than 20 comprising the steps of:(a) blowing anoxygen-containing gas into a ferrous salt reaction solution containingeither colloidal ferrous hydroxide which is obtained by reacting anaqueous ferrous salt solution with less than one equivalent of anaqueous hydroxide solution based on Fe²⁺, in said aqueous ferrous saltsolution or iron-containing colloidal precipitates which are obtained byreacting an aqueous ferrous salt solution with less than one equivalentof an aqueous alkali carbonate solution or an aqueous hydroxide andcarbonate solution based on Fe²⁺ in said aqueous ferrous salt solution,at a temperature not higher than 80° C. so as to oxidize said colloidalferrous hydroxide or iron-containing colloidal precipitates and toproduce acicular goethite nucleus particles through green rust which isproduced at a pH of 5 to 7, wherein (i) from 0.01 to 5.0 mol % ascorbicacid or a salt thereof calculated as ascorbic acid based on Fe in theferrous salt reaction solution and (ii) at least one compound selectedfrom the group consisting of compounds containing P, Si and Al arepresent in the solution before said acicular goethite nucleus particlesare produced; and (b) growing said acicular goethite nucleus particlesby blowing an oxygen containing gas into the ferrous salt reactionsolution containing not less than 10 mol % of the acicular goethitenucleus particles based on the total amount of goethite particlesproduced in the process, at (1) a pH of 3 to 6 at a temperature lessthan 90° C., (2) a pH of 8 to 10 at a temperature less than 80° , or (3)a pH not less than 11 at a temperature less than 80° C., so as toproduce acicular goethite particles.
 8. The process according to claim7, wherein (iii) 0.1 to 7.0 mol % of a zinc compound based on Fe in theferrous salt reaction solution is present in said solution in additionto (i) and (ii).
 9. The process according to claim 7, wherein the growthreaction is conducted at a temperature of 30° to 55° C. according to theprocedure (2) or (3).
 10. The process according to claim 7, wherein thegrowth reaction is conducted at a temperature of 30° to 90° C. accordingto the procedure (1).
 11. A process for producing acicular magnetic ironoxide particles comprising the step of:heat-treating in a reducing gasthe acicular goethite particles obtained by the process according toclaim 7 or 8, thereby producing acicular magnetite particles.
 12. Aprocess for producing acicular magnetic iron oxide particles comprisingthe steps of:heat-treating the acicular goethite particles obtained bythe process according to claim 7 or 8 at 300° to 700° C., therebyproducing acicular hematite particles; and heat-treating the acicularhematite particles in a reducing gas, thereby producing acicularmagnetite particles.
 13. The process according to claim 11 or 12,further comprising and additional step of oxidizing the acicularmagnetite particles, thereby producing acicular maghemite particles. 14.A process for producing acicular magnetic iron oxide particlescomprising the steps of:dispersing the acicular magnetite particlesobtained according to claim 11 or 12 or acicular maghemite particlesobtained according to claim 13 as precursor particles in an alkalinesuspension containing either cobalt hydroxide or cobalt hydroxide andferrous hydroxide wherein said suspension has a Co content of 0.1 to21.0 atomic % based on Fe of said precursor particles; and heat-treatingat a temperature of 50° to 100° C. the resultant aqueous dispersion,thereby obtaining acicular magnetite particles or acicular maghemiteparticles modified with Co or Co and Fe²⁺.